High extinction ratio and low crosstalk compact optical switches

1. An optical switch, comprising: a first birefringent polarization beam displacer configured to separate an input optical beam into a first beam component having a first polarization and a second beam component having a second polarization, wherein the first polarization is orthogonal to the second polarization; a polarization modulator operable in at least first and second states configured to rotate the polarization of beams by 0 or 90 degrees, wherein the polarization modulator is positioned in optical paths of the first beam component and the second beam component, wherein the polarization of the first beam component is rotated by 0 degrees when the first beam component passes through the polarization modulator while the polarization modulator is in the first state and by 90 degrees when the first beam component passes through the polarization modulator while the polarization modulator is in the second state, and the polarization of the second beam component is rotated by 90 degrees when the second beam component passes through the polarization modulator while the polarization modulator is in the first state and by 0 degrees when the second beam component passes through the polarization modulator while the polarization modulator is in the second state; a second birefringent polarization beam displacer optically coupled to the polarization modulator at a side opposite to the first birefringent polarization beam displacer; and a reflector positioned to reflect beams output from the second birefringent polarization beam displacer so that the reflected beams pass through the second birefringent polarization beam displacer, the polarization modulator, and the first birefringent polarization beam displacer, wherein the first birefringent polarization beam displacer is configured to combine the reflected beams into an output signal which is sent to a first output port when the polarization modulator is in the first state and to a second output port when the polarization modulator is in the second state.

2. The optical switch of claim 1 , wherein the polarization modulator includes a first pixel and a second pixel, the first pixel being positioned in the optical path of the first beam component and the second pixel being positioned in the optical path of the second beam component.

3. The optical switch of claim 1 , further comprising a glass compensating plate configured to compensate for polarization mode dispersion, wherein the glass compensating plate is optically coupled between the first birefringent polarization beam displacer and a portion of the polarization modulator.

4. The optical switch of claim 1 , wherein the polarization modulator includes a first pixel positioned in the optical path of the first beam component, a second pixel positioned in the optical path of the second beam component, a third pixel positioned in the optical paths of the reflected beams, and a fourth pixel positioned in the optical paths of the reflected beams.

5. The optical switch of claim 4 , wherein the first and third pixels are coupled and cause rotation of the polarization of the beams passing therethrough by the same amount.

6. The optical switch of claim 4 , wherein the first and third pixels cause rotation of the polarization of incident beam components by 90 degrees when the polarization modulator is in the first state and wherein the second and fourth pixels cause rotation of the polarization of incident beam components by 90 degrees when the polarization modulator is in the second state.

7. The optical switch of claim 4 , wherein the first, second, third, and fourth pixels reside in a same plane.

8. The optical switch of claim 1 , further comprising an input port through which the input optical beam is provided, wherein the first and second output ports are positioned on the same side as the input port.

9. A method for switching an optical signal received through an input port between a first output port and a second output port, comprising: passing an input optical signal through a first birefringent polarization beam displacer and separating the input optical signal into a first beam component with a first polarization and a second beam component with a second polarization; passing the first and second beam components through a polarization modulator while the polarization modulator is in a first state, wherein the polarization of the first beam component is rotated by 0 degrees when the first beam component passes through the polarization modulator and the polarization of the second beam component is rotated by 90 degrees when the second beam component passes through the polarization modulator; passing the first and second beam components output from the polarization modulator through a second birefringent polarization beam displacer; reflecting beams output from the second birefringent polarization beam displacer; passing the reflected beams through the second birefringent polarization beam displacer, the polarization modulator that is in the first state, and the first birefringent polarization beam displacer to produce an output signal at one of the first and second output ports; and controlling the polarization modulator to be in a second state to produce an output signal at the other one of the first and second output ports.

10. The method of claim 9 , wherein the polarization modulator includes a first pixel and a second pixel, and the first beam component is passed through the first pixel and the second beam component is passed through the second pixel.

11. The method of claim 10 , wherein the polarization of the first beam component is rotated by 90 degrees when the first beam component passes through the first pixel and the polarization of the second beam component is rotated by 0 degrees when the second beam component passes through the second pixel when the polarization modulator is in the second state.

12. The method of claim 11 , wherein the polarization modulator further includes a third pixel and a fourth pixel, and the reflected beams are passed through the third and fourth pixels.

13. The method of claim 12 , wherein the first and third pixels are coupled and cause rotation of the polarization of the beams passing therethrough by the same amount.

14. An optical switch, comprising: a first birefringent polarization beam displacer configured to separate an input optical beam into a first beam component having a first polarization and a second beam component having a second polarization, wherein the first polarization is orthogonal to the second polarization; a polarization modulator having a single pixel that is positioned in optical paths of the first beam component and the second beam component to rotate the polarization of incident beam components by 90 degrees each time the incident beam components pass through the single pixel; a half-wave plate positioned between the first birefringent polarization beam displacer and the polarization modulator and in the optical path of the first beam component but not in the optical path of the second beam component; a second birefringent polarization beam displacer optically coupled to the polarization modulator at a side opposite to the first birefringent polarization beam displacer; and a reflector positioned to reflect beams output from the second birefringent polarization beam displacer so that the reflected beams pass through the second birefringent polarization beam displacer, the single pixel of the polarization modulator, and the first birefringent polarization beam displacer to produce an output signal at one of first and second output ports.

15. The optical switch of claim 14 , wherein an axis of the half-wave plate is aligned at 45 degrees relative to a principal axis of the polarization modulator.

16. An optical switch, comprising: a first birefringent polarization beam displacer configured to separate an input optical beam into a first beam and a second beam; a polarization modulator operable in at least first and second states configured to rotate the polarization of the first and second beams by 0 or 90 degrees when the first and second beams are transmitted therethrough; a second birefringent polarization beam displacer optically coupled to the polarization modulator at a side opposite to the first birefringent polarization beam displacer and positioned to receive the first and second beams passing through the polarization modulator; and a reflector positioned to reflect the first and second beams output from the second birefringent polarization beam displacer so that the reflected beams pass through the second birefringent polarization beam displacer and the polarization modulator, and are combined by the first birefringent polarization beam displacer into a single output beam which is sent to a first output port when the polarization modulator is in the first state and to a second output port when the polarization modulator is in the second state.